In this cross, all offspring will have straight wings since the homozygous fly can only pass on the dominant allele for straight wings (SS) while the heterozygous fly can pass on either straight (S) or curled wings (s). Therefore, all offspring will inherit one straight wing allele, resulting in them having straight wings.
A fruit fly can lay up to 100-200 eggs in one batch.
If one fruit fly is heterozygous for long wings and the other is homozygous for short wings, the expected percentage of their offspring having long wings would be 50%. This is because when the long-winged parent passes on the dominant long-wing allele and the short-winged parent passes on the recessive short-wing allele, the offspring would have one of each allele, resulting in the offspring having long wings.
There would be a 50% chance of the offspring having gray body color and a 50% chance of having black body color. This is because in the offspring, 50% would inherit the gray allele from the gray fruit fly parent, while the other 50% would inherit the black allele from the black fruit fly parent.
You would expect 50% of the offspring to have black bodies. This is because the offspring will inherit one allele for black body color from the black parent, and one allele for gray body color from the heterozygous gray parent. The black allele is dominant over the gray allele.
In this cross, all offspring will have straight wings since the homozygous fly can only pass on the dominant allele for straight wings (SS) while the heterozygous fly can pass on either straight (S) or curled wings (s). Therefore, all offspring will inherit one straight wing allele, resulting in them having straight wings.
All offspring would have red eyes because the gene for red eyes is dominant over the gene for vermilion eyes. The offspring would all be heterozygous for eye color, inheriting one red-eyed allele from the female and one vermilion-eyed allele from the male.
A fruit fly can lay up to 100-200 eggs in one batch.
If one fruit fly is heterozygous for long wings and the other is homozygous for short wings, the expected percentage of their offspring having long wings would be 50%. This is because when the long-winged parent passes on the dominant long-wing allele and the short-winged parent passes on the recessive short-wing allele, the offspring would have one of each allele, resulting in the offspring having long wings.
There would be a 50% chance of the offspring having gray body color and a 50% chance of having black body color. This is because in the offspring, 50% would inherit the gray allele from the gray fruit fly parent, while the other 50% would inherit the black allele from the black fruit fly parent.
A normal male fruit fly has two sets of chromosomes: one set of X and one set of Y chromosomes. This combination determines the male sex of the fruit fly.
A fruit fly typically has around 14,000 genes in its genome.
You would expect 50% of the offspring to have black bodies. This is because the offspring will inherit one allele for black body color from the black parent, and one allele for gray body color from the heterozygous gray parent. The black allele is dominant over the gray allele.
There are many religions that have an offspring. Catholicism is one of them.
Fruit flies have eight chromosomes. These chromosomes contain the genetic material that determines traits and characteristics of the fruit fly.
dingoes can have a range from one to ten offspring.
The reproductive rate of a fruit fly can vary depending on factors like temperature and food availability, but on average, a female fruit fly can lay up to 500 eggs in her lifetime. This high reproductive rate is one reason why fruit flies are able to multiply rapidly in favorable conditions.